1st Edition
Electronically Scanned Arrays MATLAB® Modeling and Simulation
"[Contains] more lengthy mathematical derivations than most {comparable books] … for arrays, provides for a unique, stand-alone mathematical description that can be adopted by anyone trying to communicate the theoretical foundation for their array design…has insights from a practitioner that are unique. The MATLAB® scripts alone are worth the price."
—Daniel C. Ross, Ph. D, Northrop Grumman Corporation
Electronically Scanned Arrays: MATLAB® Modeling and Simulation is considered the first book to provide comprehensive modeling/simulation programs used to design and analyze Electronically Scanned Arrays (ESA), a key technology internationally in the scientific and engineering communities.
Several books have been written about ESAs, but most cover only fundamental theory. Few, if any, provide the insightful, easy-to-use simulation tools found in this book. Obviously, MATLAB® is one of the greatest tools available for exploring and understanding science and engineering concepts, and we use MATLAB functions to easily and instantly calculate ESA patterns. However, to achieve a truly insightful and in-depth analysis of subarray architectures, conformal arrays, etc., it is imperative that users first develop a firm grasp of ESA fundamentals.
Covers largely unexplored topics, such as reliability aspects and the application of ESAs in space
This volume helps readers build that elemental understanding of how ESAs work. It also provides code to run as an aid, so that readers don’t have to start from scratch. The book expands on ESA principles and provides a modeling framework, using MATLAB to model applications of ESAs (i.e. pattern optimization, space-based applications, and reliability analysis). Presented code serves as an excellent vehicle to help readers master the analysis and simulation of ESAs.
Exploring how difficult problems can be simplified with short, elegant solutions, this is an invaluable resource for students and others new to ESAs, as well as experienced practicing engineers who model ESAs at the systems level.
Electronically Scanned Array Fundamentals—Part 1, A.D. Brown
General One-Dimensional Formulation
ESA Fundamental Topics
One-Dimensional Pattern Synthesis
Conformal Arrays
MATLAB Program and Function Listings
Electronically Scanned Array Fundamentals—Part 2, A.D. Brown
Two-Dimensional ESA Pattern Formulation
ESA Spatial Coordinate Definitions
Sine Space Representation
ESA Element Grid
Two-Dimensional Pattern Synthesis Analysis
MATLAB Program and Function Listings
Subarrray Beamforming, A.D. Brown
Subarray Pattern Formulation
Subarray Beamforming
Overlapped Subarrays
MATLAB Program Listings
Pattern Optimization, D. Boeringer
Stochastic Pattern Optimization Overview
Pattern Optimization Implementation
MATLAB Program and Function Listings
Spaceborne Application of Electronically Scanned Arrays, T. Cooke
Two-Body Orbit Propagation
Coordinate Systems
Computing Field of View
Projecting Antenna Patterns to Geodetic Coordinates
MATLAB Program Listings
Electronically Scanned Array Reliability, J. Miller
Probability of Failed Elements
Mean Time between Failure (MTBF)
Effects of Module Failures on 1D and 2D Antenna Patterns
Effect of Module Failures on the Radar Range Equation
MATLAB Program Listings
Appendix A: Array Factor (AF) Derivation
Appendix B: Instantaneous Bandwidth (IBW) Derivation
Appendix C: Triangular Grating Lobes Derivation
Index
Biography
Arik Brown received his BS degree in electrical engineering from the Massachusetts Institute of Technology in 1993. He also received his MS and Ph.D from the University of Michigan in Electrical Engineering in 1995 and 2000 respectively. Arik was a member of the University of Michigan's Radiation Laboratory in the Computational Electromagnetics Laboratory working with Dr. John L. Volakis who is the current director of the Ohio State University ElectroScience Laboratory.
Arik joined Northrop Grumman Electronic Systems in 2000. While at Northrop he has been involved in radiator design, array pattern synthesis, system level analysis of antenna architectures and system architecture design. He has worked on various airborne and space platform programs. Arik also teaches several internal courses for the Antenna Department's Antenna Fundamental Classes and also an Antenna System's Design class. Arik also teaches an Introductory Electronically Steered Array class for potential and existing customers.
Arik has been a Northrop Grumman Presidential Leadership Award recipient twice, has multiple technical publications, and has received several Trade Secret awards. He currently works in the System Engineering Integration & Test Division as a Senior Advisory Systems Architect.